The Marine Exporation robots in DSME Robot Pavilion at Yeosu EXPO 2012
A compilation of video footage captured from the University of Aberdeen’s Hadal-Lander in the Mariana Trench from 5000m to 10,545 m deep. The large fish inhabit the shallower depth (5000 to 6500m) are rat-tails, cusk eels and eel pouts. At the mid depths (6500 to 8000m) are the supergiant amphipods and the small pink snailfish. The fragile snailfish at 8145m is now the deepest living fish. At depth greater than 8500m, only large swarms of small scavenging amphipods are visible. The footage was taken during the HADES-M cruise on Schmidt Ocean Institute’s Research Vessel ‘Falkor’.
I found the remains of this RoboFish when we were tidying my daughter's old house when she was moving out. I put it to one side intending to see if it was repairable and today I found time to have a look at it. I put a home made tail on it and spent a little time adjusting the balance and buoyancy and it really seems too cute to take apart so if you want to see one dissected have a look at the video by chen yadid
DRU was the first free swimming animatronic figure ever created.
Shot and Directed by Roger Holzberg
Project Concepted and Produced by Roger Holzberg
Project I worked on with Amy Maxmen for Nautilus Magazine.
Robotic fish in South Korea - very advanced, very strong, mostly autonomous. They use a laser beam to determine distance from objects and amend their swimming path to suit.
Serena Booth and Lezhi Li
GSD 0678 | Fall 2014
Informal Robotics
New Paradigms for Design and Construction
Harvard University Graduate School of Design
Chuck Hoberman, Instructor
Jonathan Grinham, Teaching Fellow / Dan Aukes, Research Fellow
SwimSwallow is an abstractly bio-inspired interpretation of a ?sh. The piece is designed to be laser cut from acrylic, and is then constructed with taped hinges and two servos for mouth and tail control respectively. All hinges are constructed in the ?at orientation for the sake of precision, and tabs then form a rigid linkage for stability.
The opening and closing of the mouth is achieved through spherical linkage mechanism, whereas the propulsion is applied by flipping the tail as the result of a parallel linkage mechanism. This ?ipping action also serves to steers the fish underwater.
The very beginning to our new Burning Man 2017 project.
A new miniature robot developed by EPFL researchers can swim with fish, learn how they communicate with each other and make them change direction or come together. These capabilities have been proven on schools of zebrafish.
I received my Mutsu from Japan last week and am loving it so far! This bot is pretty simple, but absolutely adorable.
TU Delft student Sander van den Berg has created a low-cost, energy-efficient robotic fish that can move through water faster than any other.
The Industrial Design Engineering masters student created the high-speed underwater drone as his graduate project from the Delft University of Technology.
The prototype robot — coloured bright orange like the clown fish from Finding Nemo — swims at a record-breaking 0.85 metres a second.
Sometimes #CIA needs to get creative when collecting intelligence. Charlie, for instance, is a robotic catfish that collects water samples. While never used operationally, the unmanned underwater vehicle (UUV) fish was created to study aquatic robot technology.